JP6987972B2 - Circuit forming method and circuit forming device - Google Patents

Description

The present invention relates to a circuit forming method for forming a circuit in which an electronic component is placed in a cavity of a resin laminate formed of a curable resin and the electronic component is electrically connected, and a circuit forming apparatus.

In recent years, using the technique described in the following patent document, an electronic component is placed in a cavity of a resin laminate formed of a curable resin, and a circuit in which the electronic component is electrically connected is formed. Equipment etc. are being developed.

Japanese Unexamined Patent Publication No. 7-040445

The challenge is to properly form the wiring that electrically connects the electronic components placed in the cavity of the resin laminate.

In order to solve the above problems, in the present specification, a resin laminate forming a resin laminate having a cavity is formed by laminating a plurality of resin layers obtained by curing a curable resin discharged in a thin film form. A step, a mounting step of mounting an electronic component with an electrode facing upward in the cavity of the resin laminate, and a conductive paste on the electrode of the electronic component mounted in the cavity. A step of forming a conductive portion for forming a conductive portion composed of the electrode and the conductive paste by applying the conductive paste so that the height dimension of the conductive paste is at least half of the dimensional tolerance of the electronic component. After the conductive portion is formed , a plurality of resin layers obtained by curing the curable resin discharged in the form of a thin film are laminated to form a coating body that covers the electronic component placed in the cavity. A coating body forming step, a removal step of removing the surface of the covering body so that the conductive portion composed of the electrodes of the electronic component covered with the covering body is exposed, and a surface of the covering body. A wiring electrically connected to the conductive portion of the electronic component exposed by removal is formed by linearly discharging a metal-containing liquid containing metal fine particles and firing the metal-containing liquid by laser irradiation. A circuit forming method including a wiring forming step is disclosed.

Further, in order to solve the above problems, in the present specification, a plurality of resin layers obtained by curing a curable resin discharged in a thin film form are laminated to form a resin laminate having a cavity. A conductive paste is applied to a body forming device, a mounting device for mounting an electronic component with an electrode facing upward in the cavity of the resin laminate, and an electrode of the electronic component mounted in the cavity. A conductive portion forming apparatus for forming a conductive portion composed of the electrode and the conductive paste by applying the conductive paste so that the height dimension of the conductive paste is at least half of the dimensional tolerance of the electronic component. A coating body that covers the electronic component placed in the cavity by laminating a plurality of resin layers obtained by curing the curable resin discharged in the form of a thin film after the conductive portion is formed. A covering body forming device for forming the covering body, a removing device for removing the surface of the covering body so that the conductive portion composed of the electrodes of the electronic component covered with the covering body is exposed, and the covering body. By linearly discharging a metal-containing liquid containing metal fine particles to a wiring electrically connected to the conductive portion of the electronic component exposed by removing the surface, and firing the metal-containing liquid by laser irradiation. A circuit forming apparatus including a wiring forming apparatus to be formed is disclosed.

According to the present disclosure, for example, it is possible to flatten the formation surface of the wiring, and the proper formation of the wiring for electrically connecting the electronic components is ensured.

It is a figure which shows the circuit forming apparatus. It is a block diagram which shows the control device. It is sectional drawing which shows the resin laminated body which has a cavity. It is sectional drawing which shows the circuit in the state which the electronic component is mounted inside the cavity. It is sectional drawing which shows the circuit in the state which the resin laminated body is formed between a cavity and an electronic component. It is sectional drawing which shows the circuit in the state which the wiring is formed on the upper surface of a resin laminate and an electronic component. It is sectional drawing which shows the circuit in the state which the electronic component is mounted inside the cavity. It is sectional drawing which shows the circuit in the state which the electronic component is mounted inside the cavity. It is sectional drawing which shows the circuit in the state which the resin laminated body is formed between a cavity and an electronic component. It is sectional drawing which shows the circuit in the state which the conductive paste is discharged on the upper surface of the electrode of an electronic component. It is sectional drawing which shows the circuit in the state which the gap of the cavity, the resin laminate, and the resin laminate covering the electronic component is formed. It is sectional drawing which shows the circuit in the state which the surface of the resin laminate is polished. It is sectional drawing which shows the circuit in the state which the wiring is formed on the upper surface of the polished resin laminate and the electronic component.

FIG. 1 shows a circuit forming apparatus 10. The circuit forming device 10 includes a transport device 20, a first modeling unit 22, a second modeling unit 24, a mounting unit 25, a removal unit 26, and a control device (see FIG. 2) 27. The transfer device 20, the first modeling unit 22, the second modeling unit 24, the mounting unit 25, and the removal unit 26 are arranged on the base 28 of the circuit forming device 10. The base 28 has a generally rectangular shape, and in the following description, the longitudinal direction of the base 28 is orthogonal to the X-axis direction, and the lateral direction of the base 28 is orthogonal to both the Y-axis direction, the X-axis direction, and the Y-axis direction. The direction will be referred to as a Z-axis direction.

The transport device 20 includes an X-axis slide mechanism 30 and a Y-axis slide mechanism 32. The X-axis slide mechanism 30 has an X-axis slide rail 34 and an X-axis slider 36. The X-axis slide rail 34 is arranged on the base 28 so as to extend in the X-axis direction. The X-axis slider 36 is slidably held in the X-axis direction by the X-axis slide rail 34. Further, the X-axis slide mechanism 30 has an electromagnetic motor (see FIG. 2) 38, and the X-axis slider 36 moves to an arbitrary position in the X-axis direction by driving the electromagnetic motor 38. Further, the Y-axis slide mechanism 32 has a Y-axis slide rail 50 and a stage 52. The Y-axis slide rail 50 is arranged on the base 28 so as to extend in the Y-axis direction, and is movable in the X-axis direction. Then, one end of the Y-axis slide rail 50 is connected to the X-axis slider 36. The stage 52 is slidably held in the Y-axis slide rail 50 in the Y-axis direction. Further, the Y-axis slide mechanism 32 has an electromagnetic motor (see FIG. 2) 56, and the stage 52 is moved to an arbitrary position in the Y-axis direction by driving the electromagnetic motor 56. As a result, the stage 52 moves to an arbitrary position on the base 28 by driving the X-axis slide mechanism 30 and the Y-axis slide mechanism 32.

The stage 52 has a base 60, a holding device 62, and an elevating device 64. The base 60 is formed in a flat plate shape, and a substrate is placed on the upper surface. The holding devices 62 are provided on both sides of the base 60 in the X-axis direction. Then, both edges of the substrate mounted on the base 60 in the X-axis direction are sandwiched by the holding device 62, so that the substrate is fixedly held. Further, the elevating device 64 is arranged below the base 60 and raises and lowers the base 60.

The first modeling unit 22 is a unit for modeling wiring on a substrate (see FIG. 3) 70 mounted on a base 60 of a stage 52, and has a first printing unit 72 and a firing unit 74. ing. The first printing unit 72 has an inkjet head (see FIG. 2) 76, and ejects metal ink linearly onto a substrate 70 mounted on a base 60. Metal ink is a metal ink in which fine particles of metal are dispersed in a solvent. The inkjet head 76 ejects metal ink from a plurality of nozzles by, for example, a piezo method using a piezoelectric element.

The firing unit 74 has a laser irradiation device (see FIG. 2) 78. The laser irradiation device 78 is a device that irradiates the metal ink ejected on the substrate 70 with a laser, and the metal ink irradiated with the laser is fired to form wiring. In addition, firing of metal ink is a phenomenon in which the solvent is vaporized and the metal fine particle protective film is decomposed by applying energy, and the metal fine particles are brought into contact with each other or fused to increase the conductivity. be. Then, the metal ink is fired to form a metal wiring.

Further, the second modeling unit 24 is a unit for modeling a resin layer on a substrate 70 mounted on a base 60 of a stage 52, and includes a second printing unit 84, a ejection unit 85, and a curing unit 86. have. The second printing unit 84 has an inkjet head (see FIG. 2) 88, and discharges the ultraviolet curable resin onto the substrate 70 mounted on the base 60. The ultraviolet curable resin is a resin that is cured by irradiation with ultraviolet rays. The inkjet head 88 may be, for example, a piezo method using a piezoelectric element, or a thermal method in which a resin is heated to generate bubbles and discharged from a plurality of nozzles.

The discharge unit 85 has a dispense head (see FIG. 2) 89, and discharges the conductive ultraviolet curable resin onto the substrate 70 mounted on the base 60. The conductive ultraviolet curable resin is a resin in which metal fine particles are dispersed in a resin that is cured by irradiation with ultraviolet rays. Then, the resin is cured by irradiation with ultraviolet rays and contracts, so that the metal fine particles are in close contact with each other, and the conductive ultraviolet curable resin exhibits conductivity. Since the viscosity of the conductive ultraviolet curable resin is relatively high as compared with the metal ink, the dispense head 89 uses the conductive ultraviolet curable resin from one nozzle having a diameter larger than the diameter of the nozzle of the inkjet head 76. Discharge. The dispense head 89 may be, for example, a transfer head for paste transfer with a stamp, and the conductive ultraviolet curable resin may be, for example, a conductive thermosetting resin.

The cured portion 86 has an irradiation device (see FIG. 2) 92. The irradiation device 92 includes a mercury lamp or an LED as a light source, and irradiates the discharged ultraviolet curable resin with ultraviolet rays. As a result, the discharged ultraviolet curable resin is cured and a resin layer is formed. Further, the irradiation device 92 irradiates the discharged conductive ultraviolet curable resin with ultraviolet rays. As a result, the conductive ultraviolet curable resin is cured and wiring is formed.

Further, the mounting unit 25 is a unit for mounting an electronic component (see FIG. 4) 96 on a substrate 70 mounted on a base 60 of a stage 52, and has a supply unit 100 and a mounting unit 102. ing. The supply unit 100 has a plurality of tape feeders (see FIG. 2) 110 that send out the taped electronic components 96 one by one, and supplies the electronic components 96 at the supply position. The supply unit 100 is not limited to the tape feeder 110, and may be a tray-type supply device that picks up and supplies the electronic component 96 from the tray. Further, the supply unit 100 may be configured to include both a tape type and a tray type, or other supply devices.

The mounting unit 102 has a mounting head (see FIG. 2) 112 and a moving device (see FIG. 2) 114. The mounting head 112 has a suction nozzle (see FIG. 4) 118 for sucking and holding the electronic component 96. The suction nozzle 118 sucks and holds the electronic component 96 by suctioning air by supplying negative pressure from a positive / negative pressure supply device (not shown). Then, when a slight positive pressure is supplied from the positive / negative pressure supply device, the electronic component 96 is separated. Further, the moving device 114 moves the mounting head 112 between the supply position of the electronic component 96 by the tape feeder 110 and the substrate 70 mounted on the base 60. As a result, in the mounting portion 102, the electronic component 96 supplied from the tape feeder 110 is held by the suction nozzle 118, and the electronic component 96 held by the suction nozzle 118 is mounted on the substrate 70.

Further, the removal unit 26 has a grinder (see FIG. 2) 119, and the surface of the resin layer formed by irradiation with ultraviolet rays is removed by polishing with the grinder 119.

Further, as shown in FIG. 2, the control device 27 includes a controller 120 and a plurality of drive circuits 122. The plurality of drive circuits 122 include the electromagnetic motors 38 and 56, a holding device 62, an elevating device 64, an inkjet head 76, a laser irradiation device 78, an inkjet head 88, a dispense head 89, an irradiation device 92, a tape feeder 110, and a mounting head 112. , Is connected to the mobile device 114 and the grinder 119. The controller 120 includes a CPU, ROM, RAM, etc., and is mainly a computer, and is connected to a plurality of drive circuits 122. As a result, the operation of the transfer device 20, the first modeling unit 22, the second modeling unit 24, the mounting unit 25, and the removal unit 26 is controlled by the controller 120.

In the circuit forming apparatus 10, the electronic component 96 is mounted on the substrate 70 and the wiring is formed by the above-described configuration, so that the circuit is formed. However, there is a possibility that the circuit cannot be formed properly by the conventional method. be. Specifically, when the circuit is formed by the conventional method, the substrate 70 is set on the base 60 of the stage 52, and the stage 52 is moved below the second modeling unit 24. Then, in the second modeling unit 24, as shown in FIG. 3, the resin laminate 130 is formed on the substrate 70. The resin laminate 130 has a cavity 132 for mounting the electronic component 96, and ejects ultraviolet curable resin from the inkjet head 88 and irradiates the ejected ultraviolet curable resin with ultraviolet rays by an irradiation device 92. Is formed by repeating.

Specifically, in the second printing unit 84 of the second modeling unit 24, the inkjet head 88 ejects the ultraviolet curable resin into a thin film on the upper surface of the substrate 70. At this time, the inkjet head 88 ejects the ultraviolet curable resin so that a predetermined portion on the upper surface of the substrate 70 is generally exposed in a rectangular shape. Subsequently, when the ultraviolet curable resin is discharged in the form of a thin film, the irradiation device 92 irradiates the thin film form of the ultraviolet curable resin with ultraviolet rays in the cured portion 86. As a result, a thin-film resin layer 133 is formed on the substrate 70.

Subsequently, the inkjet head 88 ejects the ultraviolet curable resin into a thin film only on the upper portion of the thin film resin layer 133. That is, the inkjet head 88 ejects the ultraviolet curable resin into a thin film on the thin film resin layer 133 so that a predetermined portion on the upper surface of the substrate 70 is generally exposed in a rectangular shape. Then, the irradiation device 92 irradiates the ultraviolet curable resin discharged in the form of a thin film with ultraviolet rays, whereby the thin film-like resin layer 133 is laminated on the thin-film resin layer 133. In this way, the ejection of the ultraviolet curable resin onto the thin film-shaped resin layer 133 excluding the generally rectangular portion on the upper surface of the substrate 70 and the irradiation of ultraviolet rays are repeated, and the plurality of resin layers 133 are laminated. As a result, the resin laminate 130 having the cavity 132 is formed.

When the resin laminate 130 is formed by the procedure described above, the stage 52 is moved below the mounting unit 25. In the mounting unit 25, the electronic component 96 is supplied by the tape feeder 110, and the electronic component 96 is held by the suction nozzle 118 of the mounting head 112. Then, the mounting head 112 is moved by the moving device 114, and the electronic component 96 held by the suction nozzle 118 is placed inside the cavity 132 of the resin laminate 130 as shown in FIG. At this time, the electronic component 96 is placed inside the cavity 132 with the electrode 162 facing upward.

When the electronic component 96 is mounted inside the cavity 132, the stage 52 is moved below the second modeling unit 24 and, as shown in FIG. 5, the gap between the cavities 132, that is, the inner wall surface that partitions the cavity 132. A resin laminate 150 is formed between the electronic component 96 and the electronic component 96. The resin laminate 150 is formed by repeating the ejection of the ultraviolet curable resin by the inkjet head 88 and the irradiation of ultraviolet rays by the irradiation device 92, similarly to the resin laminate 130.

Next, when the resin laminate 150 is formed in the gap of the cavity 132, the stage 52 is moved below the first modeling unit 22. Then, in the first printing unit 72, the metal ink is linearly ejected onto the resin laminates 130 and 150 by the inkjet head 76 according to the circuit pattern. At this time, as shown in FIG. 6, the metal ink 160 is linearly ejected so as to connect the electrode 162 of the electronic component 96 and another electrode (not shown). Subsequently, in the firing unit 74, the ejected metal ink 160 is irradiated with a laser by the laser irradiation device 78. As a result, the metal ink 160 is fired, and the wiring 166 connecting the electrodes is formed.

As described above, in the conventional method, the electronic component 96 is placed in the cavity 132 of the resin laminate 130, and the resin laminate 150 is formed in the gap of the cavity 132, so that the electronic component 96 exposes the electrode 162. In this state, it is embedded in the resin laminates 130 and 150. Then, the metal ink 160 is linearly ejected onto the upper surfaces of the resin laminates 130 and 150 and the electronic component 96 and fired by laser irradiation, whereby the electrode 162 of the electronic component 96 is electrically connected by wiring 166. ..

However, there is a possibility that the wiring 166 cannot be properly formed due to the dimensional tolerance of the electronic component 96, the flatness of the surfaces of the resin laminates 130 and 150, the wettability of the resin laminate 150 to the electrodes, and the like. Specifically, for example, when the dimension of the electronic component 96 is smaller than the reference dimension, the upper surface of the electronic component 96 is located below the upper surface of the resin laminate 130 as shown in FIG. 7. Even if the resin laminate 150 is formed in the gap of the cavity 132, the wiring 166 may not be properly formed due to the height difference between the upper surface of the electronic component 96 and the upper surface of the resin laminate 130, and there is a risk of disconnection. When the size of the electronic component 96 is larger than the reference dimension, the upper surface of the electronic component 96 is located above the upper surface of the resin laminate 130, and the upper surface of the electronic component 96 and the resin laminate 130 are located above the upper surface of the resin laminate 130, as shown in FIG. Due to the height difference from the upper surface of the wire, the wiring 166 may not be formed properly and may be broken.

Further, when the resin laminates 130 and 150 are formed, if the surface of the resin laminates 130 and 150 is a uniform flat surface, the wiring 166 can be appropriately formed on the surface of the resin laminates 130 and 150. If the surfaces of the resin laminates 130 and 150 have irregularities, waviness, etc., the wiring 166 may not be properly formed and may be broken. Further, when the resin laminate 150 is formed in the gap of the cavity 132, the metal ink discharged in the gap of the cavity 132 gets wet on the upper surface of the electronic component 96, and as shown in FIG. 9, the electronic component 96 The electrode 162 of the above may be covered with the resin laminate 150. In such a case, it is not possible to form the wiring 166 that electrically connects the electrodes 162 of the electronic component 96.

In view of this, in the circuit forming apparatus 10, the surface of the resin laminate is made into a uniform flat surface by polishing the grinder 119, and the electrode 162 of the electronic component 96 is electrically mounted on the uniform flat surface. Wiring 166 for connecting is formed. Specifically, as shown in FIG. 7, when the electronic component 96 is mounted inside the cavity 132, the stage 52 is moved below the second modeling unit 24. Then, as shown in FIG. 10, the dispense head 89 discharges the conductive ultraviolet curable resin 170 onto the upper surface of the electrode 162 of the electronic component 96. At this time, the dispense head 89 discharges the conductive ultraviolet curable resin 170 so that the height dimension of the conductive ultraviolet curable resin 170 is at least half the dimensional tolerance of the electronic component 96. As a result, even in the electronic component 96 having the smallest dimensional tolerance, the upper end of the conductive ultraviolet curable resin 170 protrudes above the upper surface of the resin laminate 130. Then, the conductive ultraviolet curable resin 170 is irradiated with ultraviolet rays by the irradiation device 92, so that the conductive ultraviolet curable resin 170 exhibits conductivity.

When the conductive ultraviolet curable resin 170 is discharged to the upper surface of the electrode 162 of the electronic component 96 and is irradiated with ultraviolet rays, as shown in FIG. 11, the gap between the cavities 132, the upper surface of the resin laminate 130, and the electronic component 96 The resin laminate 180 is formed so as to cover and. The resin laminate 180 is formed by repeating the ejection of the ultraviolet curable resin by the inkjet head 88 and the irradiation of ultraviolet rays by the irradiation device 92, similarly to the resin laminate 130. At this time, the resin laminate 180 is formed so that the thickness dimension of the resin laminate 180 from the upper surface of the resin laminate 130 is at least half the dimensional tolerance of the electronic component 96. As a result, the upper surface of the electronic component 96 is covered with the resin laminate 180 even for the electronic component 96 having the maximum dimensional tolerance.

Next, when the resin laminate 180 is formed, the stage 52 is moved below the removal unit 26. Then, as shown in FIG. 12, the surface of the resin laminate 180 is polished by the grinding machine 119 so that the conductive ultraviolet curable resin 170 is exposed to obtain a uniform flat surface. The amount of polishing of the resin laminate 180, that is, the thickness dimension to be polished is based on the height dimension of the conductive ultraviolet curable resin 170, the thickness dimension of the resin laminate 180 from the upper surface, and the like. Will be decided.

Subsequently, when the upper surface of the resin laminate 180 is polished and the conductive ultraviolet curable resin 170 is exposed, the stage 52 is moved below the first modeling unit 22, and as shown in FIG. 13, the upper surface of the resin laminate 180 is moved. A wiring 186 electrically connected to the conductive ultraviolet curable resin 170 is formed therein. That is, the metal ink is ejected so as to be connected to the conductive ultraviolet curable resin 170, and the metal ink is fired by irradiating the metal ink with a laser. As a result, the wiring 186 is formed on the upper surface of the resin laminate 180, and the electronic component 96 is electrically connected via the conductive ultraviolet curable resin 170 and the wiring 186.

As described above, in the circuit forming apparatus 10, after the conductive ultraviolet curable resin 170 is formed on the upper surface of the electrode 162 of the electronic component 96 placed in the cavity 132 of the resin laminate 130, the gap of the cavity 132 and the gap of the cavity 132 are formed. The resin laminate 180 is formed so as to cover the upper surface of the resin laminate 130 and the electronic component 96. Then, when the surface of the resin laminate 180 is polished so that the conductive ultraviolet curable resin 170 is exposed, the surface of the polished resin laminate 180 is electrically connected to the conductive ultraviolet curable resin 170. Wiring 186 is formed. As a result, the resin has a uniform flat surface by polishing regardless of the dimensional tolerance of the electronic component 96, the flatness of the surfaces of the resin laminates 130 and 150, and the wetness of the resin laminate 150 to the electrodes when the resin laminate 150 is formed. Wiring 186 can be formed on the surface of the laminated body 180, and appropriate wiring formation is ensured.

As shown in FIG. 2, the controller 120 of the control device 27 has a first laminated body forming portion 200, a component mounting portion 202, a conductive portion forming portion 203, a second laminated body forming portion 204, and polishing. It has a portion 206 and a wiring forming portion 208. The first laminated body forming portion 200 is a functional portion for forming the resin laminated body 130. The component mounting unit 202 is a functional unit for mounting the electronic component 96 in the cavity 132 of the resin laminate 130. The conductive portion forming portion 203 is formed by applying a conductive ultraviolet curable resin 170 to the upper surface of the electrode 162 of the electronic component 96 and irradiating with ultraviolet rays to form a conductive portion composed of the electrode 162 and the conductive ultraviolet curable resin 170. It is a functional part for forming. The second laminate forming portion 204 is a functional portion for forming the resin laminate 180 so as to cover the gap between the cavities 132, the upper surface of the resin laminate 130, and the electronic component 96. The polishing unit 206 is a functional unit for polishing the surface of the resin laminate 180 so that the conductive ultraviolet curable resin 170 is exposed. The wiring forming portion 208 is a functional portion for forming the resin laminate 180 electrically connected to the exposed conductive ultraviolet curable resin 170.

Further, in the above embodiment, the circuit forming apparatus 10 is an example of the circuit forming apparatus. The first modeling unit 22 is an example of a wiring forming device. The second modeling unit 24 is an example of a resin laminate forming device and a covering body forming device. The mounting unit 25 is an example of a mounting device. The removal unit 26 is an example of a removal device. The electronic component 96 is an example of an electronic component. The resin laminate 130 is an example of a resin laminate. The metal ink 160 is an example of a metal-containing liquid. The electrode 162 is an example of an electrode. The conductive ultraviolet curable resin 170 is an example of a conductive paste. The one composed of the electrode 162 and the conductive ultraviolet curable resin 170 is an example of the conductive portion. The resin laminate 180 is an example of a covering body. Wiring 186 is an example of wiring. The step executed by the first laminate forming unit 200 is an example of the resin laminate forming step. The process executed by the component mounting unit 202 is an example of the mounting process. The step executed by the conductive portion forming portion 203 is an example of the conductive portion forming step. The step executed by the second laminated body forming portion 204 is an example of the covering body forming step. The step executed by the polishing unit 206 is an example of the removing step. The process executed by the wiring forming unit 208 is an example of the wiring forming process.

The present invention is not limited to the above embodiment, and can be carried out in various embodiments with various changes and improvements based on the knowledge of those skilled in the art. For example, in the above embodiment, the conductive ultraviolet curable resin 170 is discharged on the upper surface of the electrode 162 of the electronic component 96, but even without the conductive ultraviolet curable resin 170, proper formation of wiring can be ensured. It is possible. Specifically, in the case of an electronic component having an electrode protruding from the main body of the electronic component, such as a bump, the electronic component is in a state where the electrode faces upward even without the conductive ultraviolet curable resin 170. Is placed in the cavity 132, the electrodes project upward. Then, when the resin laminate 180 is formed so as to cover the gap between the cavities 132, the upper surface of the resin laminate 130, and the electronic components, the surface of the resin laminate 180 is polished so that the electrodes are exposed. To. Thereby, the wiring 186 electrically connected to the electronic component can be formed on the uniform flat surface. In this case, the conductive portion of the electronic component is formed only by the electrodes.

10: Circuit forming device 22: First modeling unit (wiring forming device) 24: Second modeling unit (resin laminate forming device) (cover body forming device) 25: Mounting unit (mounting device) 26: Removal unit (removal) Equipment) 96: Electronic parts 130: Resin laminate 160: Metal ink (metal-containing liquid) 162: Electrode (conductive part) 170: Conductive ultraviolet curable resin (conductive paste) (conductive part) 180: Resin laminate (coating) Body) 186: Wiring 200: First laminated body forming part (resin laminated body forming part) 202: Parts mounting part (mounting step) 203: Conductive part forming part (conductive part forming step) 204: Second laminated body forming Part (cover body forming step) 206: Polished part (removal step) 208: Wiring forming part (wiring forming step)

Claims (2)

A resin laminate forming step of forming a resin laminate having a cavity by laminating a plurality of resin layers obtained by curing a curable resin discharged in a thin film form.
A mounting step of mounting an electronic component with the electrodes facing upward in the cavity of the resin laminate, and a mounting step.
By applying the conductive paste to the electrode of the electronic component placed in the cavity so that the height dimension of the conductive paste is at least half of the dimensional tolerance of the electronic component, the electrode and the said. A conductive portion forming step of forming a conductive portion composed of a conductive paste, and a conductive portion forming step.
After the conductive portion is formed , a plurality of resin layers obtained by curing the curable resin discharged in the form of a thin film are laminated to form a covering body for covering the electronic component placed in the cavity. Cover forming process and
Wherein As before Kishirube conductive portion of said electronic component coated with a coating member to expose a removal step of removing the surface of the jacket,
A metal-containing liquid containing metal fine particles is linearly discharged from a wiring electrically connected to the conductive portion of the electronic component exposed by removing the surface of the coating body, and the metal-containing liquid is discharged by laser irradiation. A circuit forming method including a wiring forming step of forming by firing. A resin laminate forming apparatus that forms a resin laminate having a cavity by laminating a plurality of resin layers obtained by curing a curable resin discharged in a thin film form.
A mounting device for mounting an electronic component with an electrode facing upward in the cavity of the resin laminate, and a mounting device.
By applying the conductive paste to the electrode of the electronic component placed in the cavity so that the height dimension of the conductive paste is at least half of the dimensional tolerance of the electronic component, the electrode and the said. A conductive part forming device for forming a conductive part composed of a conductive paste, and a conductive part forming device.
After the conductive portion is formed , a plurality of resin layers obtained by curing the curable resin discharged in the form of a thin film are laminated to form a covering body for covering the electronic component placed in the cavity. Cover body forming device and
A removing device that removes the surface of the covering so that the conductive portion formed of the electrodes of the electronic component covered with the covering is exposed.
A metal-containing liquid containing metal fine particles is linearly discharged from a wiring electrically connected to the conductive portion of the electronic component exposed by removing the surface of the coating body, and the metal-containing liquid is discharged by laser irradiation. A circuit forming device including a wiring forming device formed by firing.

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